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Balancing selection

 
Sci-Tech Dictionary: balanced polymorphism
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(′bal·ənst ¦päl·i′mör′fiz·əm)

(genetics) Maintenance in a population of two or more alleles in equilibrium at frequencies too high to be explained, particularly for the rarer of them, by mutation; commonly due to the selective advantage of a heterozygote over both homozygotes.

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Genetics Encyclopedia: Balanced Polymorphism
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Balanced polymorphism is a situation in which two different versions of a gene are maintained in a population of organisms because individuals carrying both versions are better able to survive than those who have two copies of either version alone. The evolutionary process that maintains the two versions over time is called balancing selection.

Genes are carried on chromosomes. Different versions of a gene are called alleles. The standard allele found in a population is referred to as the wild-type allele. Most plants and animals have at least two copies of each chromosome, one inherited from each parent. The copies of the genes found on these homologous chromosomes may be identical or different; that is, the organism may carry two copies of one allele, or one each of two different alleles. In the first case, the organism is called homozygous for that gene, and, in the second, it is called heterozygous.

Alleles differ from each other in their sequence of nucleotides, which may change the structure and function of the protein the gene codes for. Because of this, different alleles may have different effects on an organism's appearance or ability to survive. These effects can be helpful, harmful, or neutral.

An example of balanced polymorphism can be illustrated with the set of enzymes in the liver that act like an assembly line (or, more accurately, a disassembly line) to detoxify poisons and other chemicals. Different alleles for these enzymes can affect how well an organism can protect itself from exposure to harmful chemicals. An especially active form of a detoxifying enzyme, which is encoded by a specific allele, can cause accumulation of potentially harmful intermediates. If the other allele encodes an enzyme with low activity, the potential for this enzyme to cause harm is lessened, and the benefits of its activity will be felt by the organism. If an individual has two copies of the very active allele or two copies of the low-activity allele, it may not survive well. In the first case, too much enzyme activity will result in high levels of the harmful intermediate, and in the second case, too little enzyme activity will be present for detoxification. Therefore, the best situation for the organism is to have one copy of each allele. Because of this, both copies are maintained in the population.

The effects of alleles and whether they are maintained in a population can be influenced by the environment. A classic case of balanced polymorphism in humans that is influenced by the environment is the sickle-cell allele of the β-globin gene. This gene forms part of hemoglobin, which carries oxygen in red blood cells.

Individuals who have two copies of the β-globin sickle-cell allele develop sickle-cell disease and generally do not survive into adulthood without intensive medical care. Individuals with one copy of the β-globin sickle-cell allele and one β-globin wild-type allele have red blood cells that are functional and resistant to the organism that causes malaria. Because individuals with this combination of alleles tend to survive malaria better than those who carry only the wild-type allele, the combination is advantageous to those who live in areas where malaria is present. This is called "heterozygote advantage." As a result, the beta-globin sickle-cell allele will be maintained along with the wild-type allele in populations exposed to malaria—an example of balancing selection.

Bibliography

Weaver, Robert F., and Philip W. Hedrick. Genetics, 2nd ed. Dubuque, IA: William C. Brown, 1992.

—R. John Nelson

Biology Q&A: What is balanced polymorphism?
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When a trait exists in several forms within a population, it is said to be polymorphic. Polymorphisms that maintain a stable distribution within the population over generations are known as balanced polymorphisms. Balanced polymorphism can be maintained if heterozygotes (mixtures of two types) have a fitness advantage. When this occurs, both types of alleles are maintained in the population. A classic example of this is sickle cell anemia. Individuals who are heterozygous (Hh) are resistant to malaria, dominant homozygotes (HH) are susceptible to malaria, and recessive homozygotes (hh) have sickle cell anemia. Because those who have both types of alleles and who live in malaria-prone regions are the most likely to survive long enough to produce children, both types are maintained in the population at a relatively stable rate.

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Medical Dictionary: balanced polymorphism
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n.

A system of genes in which two alleles are maintained in stable equilibrium because the heterozygote is more fit than either of the homozygotes.

Wikipedia: Balancing selection
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Balancing selection refers to a number of selective processes by which multiple alleles (different versions of a gene) are actively maintained in the gene pool of a population at frequencies above that of gene mutation. This usually happens when the heterozygotes for the alleles under consideration have a higher adaptive value than the homozygote.[1] In this way genetic polymorphism is conserved.[2][3]

Biston betularia morpha typica, the standard light-coloured Peppered Moth.
Biston betularia morpha carbonaria, the melanic Peppered Moth. The proportions of this form vary in different locations

There are three main types of natural selection: In directional selection the allele frequency for a trait continuously shifts in one direction. In stabilizing selection the frequency of the alleles of lower fitness decreases until they vanish. Balancing selection is similar but not identical to disruptive selection where individuals of extreme trait values are favored against those with average trait values. These terms are used for quantitative characters controlled by a number of genes.[4]

Evidence for balancing selection can be found in the number of alleles in a population which are maintained above mutation rate frequencies. All modern research has shown that this significant genetic variation is ubiquitous in panmictic populations. It is a genetic expression of the field experience of Darwin, Wallace and others, that natural populations in the wild are extraordinarily varied (though not all such variation is of genetic origin).

There are several mechanisms (which are not exclusive within any given population) by which balancing selection works to maintain polymorphism. The two major and most studied are heterozygote advantage and frequency dependent selection.

Contents

Mechanisms of balancing selection

Heterozygote advantage

Sickle-shaped red blood cells. This non-lethal condition in heterozygotes is maintained by balancing selection in humans of Africa and India due to its resistance to the malarial parasite. [5]
Main article: Heterozygote advantage

In heterozygote advantage, or heterotic balancing selection, an individual who is heterozygous at a particular gene locus has a greater fitness than a homozygous individual. Polymorphisms maintained by this mechanism are balanced polymorphisms.[6]

A well-studied case of heterozygote advantage is that of sickle cell anemia in humans, a hereditary disease that damages red blood cells. Sickle cell anemia is caused by the inheritance of a variant hemoglobin gene (HgbS) from both parents. In these individuals hemoglobin (protein in red blood cells that carries oxygen to the tissues) is extremely sensitive to oxygen deprivation causing short life expectancy. However, a person who inherits the sickle cell gene from one parent and a normal hemoglobin gene (HgbA) from the other parent (this person is said to be a carrier of the sickle cell trait) has a normal life expectancy (though these heterozygote individuals may suffer periodic problems).

The heterozygote is resistant to the malarial parasite which kills a large number of people each year. This is balancing selection between fierce selection against homozygous sickle-cell sufferers, and selection against the standard HgbA homozygotes by malaria. The heterozygote has a permanent advantage (a higher fitness) wherever malaria exists.[7][8]

Frequency dependent selection

Main article: Frequency dependent selection

Frequency dependent selection occurs when the fitness of a phenotype is dependent on its frequency relative to other phenotypes in a given population. In positive frequency dependent selection, the fitness of a phenotype increases as it becomes more common. In negative frequency dependent selection, the fitness of a phenotype increases as it becomes less common. For example in prey switching, rare morphs of prey are actually fitter due to predators concentrating on the more frequent morphs.

Fitness varies in time & space

The fitness of a genotype may vary greatly between larval and adult stages, or between parts of a habitat range.[9]

Selection acts at different levels

The fitness of a genotype may depend on the fitness of other genotypes in the population: this covers many natural situations where the best thing to do (from the point of view of survival and reproduction) depends on what other members of the population are doing at the time.[10]

More complex examples

Species in their natural habitat are often far more complex that the typical text-book examples.

Grove snail

The Grove Snail, Cepaea nemoralis, is famous for the rich polymorphism of its shell. The system is controlled by a series of multiple alleles. Unbanded is the top dominant trait, and the forms of banding are controlled by modifier genes (see epistasis).

Grove snail, dark yellow shell with single band.

In England the snail is regularly predated by the Song Thrush Turdus philomelos, which breaks them open on thrush anvils (large stones). Here fragments accumulate, permitting researchers to analyse the snails taken. The thrushes hunt by sight, and capture selectively those forms which match the habitat least well. Snail colonies are found in woodland, hedgerows and grassland, and the predation determines the proportion of phenotypes (morphs) found in each colony.

Two active Grove snails

A second kind of selection also operates on the snail, whereby certain heterozygotes have a physiological advantage over the homozygotes. Thirdly, apostatic selection is likely, with the birds preferentially taking the most common morph. This is the 'search pattern' effect, where a predominantly visual predator persists in targeting the morph which gave a good result, even though other morphs are available.

The polymorphism survives in almost all habitats, though the proportions of morphs varies considerably. The alleles controlling the polymorphism form a super-gene with linkage so close as to be nearly absolute. This control saves the population from a high proportion of undesirable recombinants.

To sum up, in this species predation by birds appears to be the main (but not the only) selective force driving the polymorphism. The snails live on heterogenous backgrounds, and thrush are adept at detecting poor matches. The inheritance of physiological and cryptic diversity is preserved also by heterozygous advantage in the super-gene.[11][12][13][14][15] Recent work has included the effect of shell colour on thermoregulation,[16] and a wider selection of possible genetic influences is considered by Cook.[17]

Chromosome polymorphism in Drosophila

In the 1930s Dobzhansky and his co-workers collected Drosophila pseudoobscura and D. persimilis from wild populations in California and neighbouring states. Using Painter's technique[18] they studied the polytene chromosomes and discovered that all the wild populations were polymorphic for chromosomal inversions. All the flies look alike whatever inversions they carry, so this is an example of a cryptic polymorphism. Evidence accumulated to show that natural selection was responsible:

Drosophila polytene chromosome

1. Values for heterozygote inversions of the third chromosome were often much higher than they should be under the null assumption: if no advantage for any form the number of heterozygotes should conform to Ns (number in sample) = p2+2pq+q2 where 2pq is the number of heterozygotes (see Hardy-Weinberg equilibrium).

2. Using a method invented by L'Heretier and Teissier, Dobzhansky bred populations in population cages, which enabled feeding, breeding and sampling whilst preventing escape. This had the benefit of eliminating migration as a possible explanation of the results. Stocks containing inversions at a known initial frequency can be maintained in controlled conditions. It was found that the various chromosome types do not fluctuate at random, as they would if selectively neutral, but adjust to certain frequencies at which they become stabilised.

3. Different proportions of chromosome morphs were found in different areas. There is, for example, a polymorph-ratio cline in D. robusta along an 18-mile (29 km) transect near Gatlinburg, TN passing from 1,000 feet (300 m) to 4,000 feet.[19] Also, the same areas sampled at different times of year yielded significant differences in the proportions of forms. This indicates a regular cycle of changes which adjust the population to the seasonal conditions. For these results selection is by far the most likely explanation.

4. Lastly, morphs cannot be maintained at the high levels found simply by mutation, nor is drift a possible explanation when population numbers are high.

By 1951 Dobzhansky was persuaded that the chromosome morphs were being maintained in the population by the selective advantage of the heterozygotes, as with most polymorphisms.[20][21][22]

References

  1. ^ King R.C. Stansfield W.D. & Mulligan P.K. 2006. A dictionary of genetics, 7th ed. Oxford. p44
  2. ^ http://www.answers.com/topic/balanced-polymorphism
  3. ^ Ford, E.B. (1940). "Polymorphism and taxonomy". in J. Huxley, ed.. The New Systematics. Oxford: Clarendon Press. pp. 493–513. 
  4. ^ http://www.sparknotes.com/biology/evolution/naturalselection/section1.html
  5. ^ http://en.wikipedia.org/wiki/Polymorphism_(biology)
  6. ^ Heredity. 2009. Encyclopædia Britannica. Chicago.
  7. ^ Allison A.C. 1956. The sickle-cell and Haemoglobin C genes in some African populations. Ann. Human Genet. 21, 67-89.
  8. ^ Sickle cell anemia. 2009. Encyclopædia Britannica. Chicago.
  9. ^ Ford E.B. 1965. Genetic polymorphism, p26, Heterozygous advantage. MIT Press 1965.
  10. ^ Maynard Smith J. 1998. Evolutionary genetics. Oxford. p75 and Chapter 7.
  11. ^ Cain A.J. and Currey J.D. Area effects in Cepaea. Phil. Trans. R. Soc. B 246: 1-81.
  12. ^ Cain A.J. and Currey J.D. 1968. Climate and selection of banding morphs in Cepaea from the climate optimum to the present day. Phil. Trans. R. Soc. B 253: 483-98.
  13. ^ Cain A.J. and Sheppard P.M. 1950. Selection in the polymorphic land snail Cepaea nemoralis (L). Heredity 4:275-94.
  14. ^ Cain A.J. and Sheppard P.M. 1954. Natural selection in Cepaea. Genetics 39: 89-116.
  15. ^ Ford E.B. 1975. Ecological genetics, 4th ed. Chapman & Hall, London
  16. ^ Jones J.S., Leith B.N. & Rawlings P. 1977. Polymorphism in Cepaea: a problem with too many solutions. Annual Reviews in Ecology and Systematics 8, 109-143.
  17. ^ Cook L.M. 1998. A two-stage model for Cepaea polymorphism. Phil. Trans. R. Soc. B 353, 1577-1593.
  18. ^ Painter T.S. 1933. A new method for the study of chromosome rearrangements and the plotting of chromosome maps. Science 78: 585-586.
  19. ^ Stalker H.D and Carson H.L. 1948. An altitudinal transect of Drosophila robusta. Evolution 1, 237-48.
  20. ^ Dobzhansky T. 1970. Genetics of the evolutionary process. Columbia University Press N.Y.
  21. ^ [Dobzhansky T.] 1981. Dobzhansky's genetics of natural populations. eds Lewontin RC, Moore JA, Provine WB and Wallace B. Columbia University Press N.Y.
  22. ^ Ford E.B. 1975. Ecological genetics. 4th ed. Chapman & Hall, London.
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Topics in molecular evolution
Natural selection
Models
Molecular processes

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